Global fern and lycophyte richness explained: How regional and local factors shape plot richness

Anna Weigand; Stefan Abrahamczyk; Isabelle Aubin; Claudia Bita-Nicolae; Helge Bruelheide; Cesar I. Carvajal-Hernández; Daniele Cicuzza; Lucas Erickson Nascimento da Costa; János Csiky; Jürgen Dengler; André Luís de Gasper; Greg R. Guerin; Sylvia Haider; Adriana Hernández-Rojas; Ute Jandt; Johan Reyes-Chávez; Dirk N. Karger; Phyo Kay Khine; Jürgen Kluge; Thorsten Krömer; Marcus Lehnert; Jonathan Lenoir; Gabriel M. Moulatlet; Daniela Aros-Mualin; Sarah Noben; Ingrid Olivares; Luis G. Quintanilla; Peter B. Reich; Laura Salazar; Libertad Silva-Mijangos; Hanna Tuomisto; Patrick Weigelt; Gabriela Zuquim; Holger Kreft; Michael Kessler

doi:10.1111/jbi.13782

Global fern and lycophyte richness explained: How regional and local factors shape plot richness

Anna Weigand
, Stefan Abrahamczyk
, Isabelle Aubin
, Claudia Bita-Nicolae
, Helge Bruelheide
, Cesar I. Carvajal-Hernández
, Daniele Cicuzza
, Lucas Erickson Nascimento da Costa
, János Csiky
, Jürgen Dengler
, André Luís de Gasper
, Greg R. Guerin
, Sylvia Haider
, Adriana Hernández-Rojas
, Ute Jandt
, Johan Reyes-Chávez
, Dirk N. Karger
, Phyo Kay Khine
, Jürgen Kluge
, Thorsten Krömer

Marcus Lehnert, Jonathan Lenoir, Gabriel M. Moulatlet, Daniela Aros-Mualin, Sarah Noben, Ingrid Olivares, Luis G. Quintanilla, Peter B. Reich, Laura Salazar, Libertad Silva-Mijangos, Hanna Tuomisto, Patrick Weigelt, Gabriela Zuquim, Holger Kreft, Michael Kessler

University of Zurich
University of Bonn
Natural Resources Canada
Romanian Academy
Martin Luther University Halle-Wittenberg
German Centre for Integrative Biodiversity Research (iDiv) Halle-Jena-Leipzig
Universidad Veracruzana
CAS - Xishuangbanna Tropical Botanical Garden
Universiti Brunei Darussalam
Universidade Federal de Pernambuco
University of Pecs
Zurich University of Applied Sciences
University of Bayreuth
Universidade Regional de Blumenau
University of Adelaide
University of Marburg
Zamorano University
Swiss Federal Institute for Forest, Snow and Landscape Research
Ludwig Maximilian University of Munich
Université de Picardie Jules Verne
Universidad Regional Amazónica Ikiam
University College London
Universidad Rey Juan Carlos
University of Minnesota Twin Cities
Western Sydney University
Universidad Tecnológica Indoamérica
Universidad de Ciencias y Artes de Chiapas
University of Turku
University of Göttingen

Research output: Contribution to journal › Article › peer-review

68 Scopus citations

Abstract

Aim: To disentangle the influence of environmental factors at different spatial grains (regional and local) on fern and lycophyte species richness and to ask how regional and plot-level richness are related to each other. Location: Global. Taxon: Ferns and lycophytes. Methods: We explored fern and lycophyte species richness at two spatial grains, regional (hexagonal grid cells of 7,666 km²) and plot level (300–500 m²), in relation to environmental data at regional and local grains (the 7,666 km² hexagonal grid cells and 4 km² square grid cells, respectively). For the regional grain, we obtained species richness data for 1,243 spatial units and used them together with climatic and topographical predictors to model global fern richness. For the plot-level grain, we collated a global dataset of nearly 83,000 vegetation plots with a surface area in the range 300–500 m² in which all fern and lycophyte species had been counted. We used structural equation modelling to identify which regional and local factors have the biggest effect on plot-level fern and lycophyte species richness worldwide. We investigate how plot-level richness is related to modelled regional richness at the plot's location. Results: Plot-level fern and lycophyte species richness were best explained by models allowing a link between regional environment and plot-level richness. A link between regional richness and plot-level richness was essential, as models without it were rejected, while models without the regional environment-plot-level richness link were still valid but had a worse goodness-of-fit value. Plot-level richness showed a hump-shaped relationship with regional richness. Main conclusions: Regional environment and regional fern and lycophyte species richness each are important determinants of plot-level richness, and the inclusion of one does not substitute the inclusion of the other. Plot-level richness increases with regional richness until a saturation point is reached, after which plot-level richness decreases despite increasing regional richness, possibly reflecting species interactions.

Original language	English
Pages (from-to)	59-71
Number of pages	13
Journal	Journal of Biogeography
Volume	47
Issue number	1
DOIs	https://doi.org/10.1111/jbi.13782
State	Published - 1 Jan 2020
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2019 John Wiley & Sons Ltd

Keywords

big data
macroecology
pteridophytes
regional-local richness relationship
saturation curves
structural equation modelling

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10.1111/jbi.13782

Cite this

Weigand, A., Abrahamczyk, S., Aubin, I., Bita-Nicolae, C., Bruelheide, H., I. Carvajal-Hernández, C., Cicuzza, D., Nascimento da Costa, L. E., Csiky, J., Dengler, J., Gasper, A. L. D., Guerin, G. R., Haider, S., Hernández-Rojas, A., Jandt, U., Reyes-Chávez, J., Karger, D. N., Khine, P. K., Kluge, J., ... Kessler, M. (2020). Global fern and lycophyte richness explained: How regional and local factors shape plot richness. Journal of Biogeography, 47(1), 59-71. https://doi.org/10.1111/jbi.13782

@article{d50d78ab38c24a8bbd8eb122bc0c4e37,

title = "Global fern and lycophyte richness explained: How regional and local factors shape plot richness",

abstract = "Aim: To disentangle the influence of environmental factors at different spatial grains (regional and local) on fern and lycophyte species richness and to ask how regional and plot-level richness are related to each other. Location: Global. Taxon: Ferns and lycophytes. Methods: We explored fern and lycophyte species richness at two spatial grains, regional (hexagonal grid cells of 7,666 km2) and plot level (300–500 m2), in relation to environmental data at regional and local grains (the 7,666 km2 hexagonal grid cells and 4 km2 square grid cells, respectively). For the regional grain, we obtained species richness data for 1,243 spatial units and used them together with climatic and topographical predictors to model global fern richness. For the plot-level grain, we collated a global dataset of nearly 83,000 vegetation plots with a surface area in the range 300–500 m2 in which all fern and lycophyte species had been counted. We used structural equation modelling to identify which regional and local factors have the biggest effect on plot-level fern and lycophyte species richness worldwide. We investigate how plot-level richness is related to modelled regional richness at the plot's location. Results: Plot-level fern and lycophyte species richness were best explained by models allowing a link between regional environment and plot-level richness. A link between regional richness and plot-level richness was essential, as models without it were rejected, while models without the regional environment-plot-level richness link were still valid but had a worse goodness-of-fit value. Plot-level richness showed a hump-shaped relationship with regional richness. Main conclusions: Regional environment and regional fern and lycophyte species richness each are important determinants of plot-level richness, and the inclusion of one does not substitute the inclusion of the other. Plot-level richness increases with regional richness until a saturation point is reached, after which plot-level richness decreases despite increasing regional richness, possibly reflecting species interactions.",

keywords = "big data, macroecology, pteridophytes, regional-local richness relationship, saturation curves, structural equation modelling",

author = "Anna Weigand and Stefan Abrahamczyk and Isabelle Aubin and Claudia Bita-Nicolae and Helge Bruelheide and \{I. Carvajal-Hern{\'a}ndez\}, Cesar and Daniele Cicuzza and \{Nascimento da Costa\}, \{Lucas Erickson\} and J{\'a}nos Csiky and J{\"u}rgen Dengler and Gasper, \{Andr{\'e} Lu{\'i}s de\} and Guerin, \{Greg R.\} and Sylvia Haider and Adriana Hern{\'a}ndez-Rojas and Ute Jandt and Johan Reyes-Ch{\'a}vez and Karger, \{Dirk N.\} and Khine, \{Phyo Kay\} and J{\"u}rgen Kluge and Thorsten Kr{\"o}mer and Marcus Lehnert and Jonathan Lenoir and Moulatlet, \{Gabriel M.\} and Daniela Aros-Mualin and Sarah Noben and Ingrid Olivares and \{G. Quintanilla\}, Luis and Reich, \{Peter B.\} and Laura Salazar and Libertad Silva-Mijangos and Hanna Tuomisto and Patrick Weigelt and Gabriela Zuquim and Holger Kreft and Michael Kessler",

note = "Publisher Copyright: {\textcopyright} 2019 John Wiley \& Sons Ltd",

year = "2020",

month = jan,

day = "1",

doi = "10.1111/jbi.13782",

language = "Ingl{\'e}s",

volume = "47",

pages = "59--71",

journal = "Journal of Biogeography",

issn = "0305-0270",

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Weigand, A, Abrahamczyk, S, Aubin, I, Bita-Nicolae, C, Bruelheide, H, I. Carvajal-Hernández, C, Cicuzza, D, Nascimento da Costa, LE, Csiky, J, Dengler, J, Gasper, ALD, Guerin, GR, Haider, S, Hernández-Rojas, A, Jandt, U, Reyes-Chávez, J, Karger, DN, Khine, PK, Kluge, J, Krömer, T, Lehnert, M, Lenoir, J, Moulatlet, GM, Aros-Mualin, D, Noben, S, Olivares, I, G. Quintanilla, L, Reich, PB, Salazar, L, Silva-Mijangos, L, Tuomisto, H, Weigelt, P, Zuquim, G, Kreft, H & Kessler, M 2020, 'Global fern and lycophyte richness explained: How regional and local factors shape plot richness', Journal of Biogeography, vol. 47, no. 1, pp. 59-71. https://doi.org/10.1111/jbi.13782

TY - JOUR

T1 - Global fern and lycophyte richness explained

T2 - How regional and local factors shape plot richness

AU - Weigand, Anna

AU - Abrahamczyk, Stefan

AU - Aubin, Isabelle

AU - Bita-Nicolae, Claudia

AU - Bruelheide, Helge

AU - I. Carvajal-Hernández, Cesar

AU - Cicuzza, Daniele

AU - Nascimento da Costa, Lucas Erickson

AU - Csiky, János

AU - Dengler, Jürgen

AU - Gasper, André Luís de

AU - Guerin, Greg R.

AU - Haider, Sylvia

AU - Hernández-Rojas, Adriana

AU - Jandt, Ute

AU - Reyes-Chávez, Johan

AU - Karger, Dirk N.

AU - Khine, Phyo Kay

AU - Kluge, Jürgen

AU - Krömer, Thorsten

AU - Lehnert, Marcus

AU - Lenoir, Jonathan

AU - Moulatlet, Gabriel M.

AU - Aros-Mualin, Daniela

AU - Noben, Sarah

AU - Olivares, Ingrid

AU - G. Quintanilla, Luis

AU - Reich, Peter B.

AU - Salazar, Laura

AU - Silva-Mijangos, Libertad

AU - Tuomisto, Hanna

AU - Weigelt, Patrick

AU - Zuquim, Gabriela

AU - Kreft, Holger

AU - Kessler, Michael

PY - 2020/1/1

Y1 - 2020/1/1

N2 - Aim: To disentangle the influence of environmental factors at different spatial grains (regional and local) on fern and lycophyte species richness and to ask how regional and plot-level richness are related to each other. Location: Global. Taxon: Ferns and lycophytes. Methods: We explored fern and lycophyte species richness at two spatial grains, regional (hexagonal grid cells of 7,666 km2) and plot level (300–500 m2), in relation to environmental data at regional and local grains (the 7,666 km2 hexagonal grid cells and 4 km2 square grid cells, respectively). For the regional grain, we obtained species richness data for 1,243 spatial units and used them together with climatic and topographical predictors to model global fern richness. For the plot-level grain, we collated a global dataset of nearly 83,000 vegetation plots with a surface area in the range 300–500 m2 in which all fern and lycophyte species had been counted. We used structural equation modelling to identify which regional and local factors have the biggest effect on plot-level fern and lycophyte species richness worldwide. We investigate how plot-level richness is related to modelled regional richness at the plot's location. Results: Plot-level fern and lycophyte species richness were best explained by models allowing a link between regional environment and plot-level richness. A link between regional richness and plot-level richness was essential, as models without it were rejected, while models without the regional environment-plot-level richness link were still valid but had a worse goodness-of-fit value. Plot-level richness showed a hump-shaped relationship with regional richness. Main conclusions: Regional environment and regional fern and lycophyte species richness each are important determinants of plot-level richness, and the inclusion of one does not substitute the inclusion of the other. Plot-level richness increases with regional richness until a saturation point is reached, after which plot-level richness decreases despite increasing regional richness, possibly reflecting species interactions.

AB - Aim: To disentangle the influence of environmental factors at different spatial grains (regional and local) on fern and lycophyte species richness and to ask how regional and plot-level richness are related to each other. Location: Global. Taxon: Ferns and lycophytes. Methods: We explored fern and lycophyte species richness at two spatial grains, regional (hexagonal grid cells of 7,666 km2) and plot level (300–500 m2), in relation to environmental data at regional and local grains (the 7,666 km2 hexagonal grid cells and 4 km2 square grid cells, respectively). For the regional grain, we obtained species richness data for 1,243 spatial units and used them together with climatic and topographical predictors to model global fern richness. For the plot-level grain, we collated a global dataset of nearly 83,000 vegetation plots with a surface area in the range 300–500 m2 in which all fern and lycophyte species had been counted. We used structural equation modelling to identify which regional and local factors have the biggest effect on plot-level fern and lycophyte species richness worldwide. We investigate how plot-level richness is related to modelled regional richness at the plot's location. Results: Plot-level fern and lycophyte species richness were best explained by models allowing a link between regional environment and plot-level richness. A link between regional richness and plot-level richness was essential, as models without it were rejected, while models without the regional environment-plot-level richness link were still valid but had a worse goodness-of-fit value. Plot-level richness showed a hump-shaped relationship with regional richness. Main conclusions: Regional environment and regional fern and lycophyte species richness each are important determinants of plot-level richness, and the inclusion of one does not substitute the inclusion of the other. Plot-level richness increases with regional richness until a saturation point is reached, after which plot-level richness decreases despite increasing regional richness, possibly reflecting species interactions.

KW - big data

KW - macroecology

KW - pteridophytes

KW - regional-local richness relationship

KW - saturation curves

KW - structural equation modelling

UR - https://www.scopus.com/pages/publications/85077896250

U2 - 10.1111/jbi.13782

DO - 10.1111/jbi.13782

M3 - Artículo

AN - SCOPUS:85077896250

SN - 0305-0270

VL - 47

SP - 59

EP - 71

JO - Journal of Biogeography

JF - Journal of Biogeography

IS - 1

ER -

Global fern and lycophyte richness explained: How regional and local factors shape plot richness

Abstract

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Keywords

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